I have a list in python like this:
myList = [1,14,2,5,3,7,8,12]
How can I easily find the first unused value? (in this case '4')
I came up with several different ways:
I didn't want to get the shortest code (which might be the set-difference trickery) but something that could have a good running time.
This might be one of the best proposed here, my tests show that it might be substantially faster - especially if the hole is in the beginning - than the set-difference approach:
from itertools import count, filterfalse # ifilterfalse on py2 A = [1,14,2,5,3,7,8,12] print(next(filterfalse(set(A).__contains__, count(1))))
The array is turned into a
__contains__(x) method corresponds to
x in A.
count(1) creates a counter that starts counting from 1 to infinity. Now,
filterfalse consumes the numbers from the counter, until a number is found that is not in the set; when the first number is found that is not in the set it is yielded by
len(a) = 100000, randomized and the sought-after number is
>>> timeit(lambda: next(filterfalse(set(a).__contains__, count(1))), number=100) 0.9200698399945395 >>> timeit(lambda: min(set(range(1, len(a) + 2)) - set(a)), number=100) 3.1420603669976117
len(a) = 100000, ordered and the first free is
>>> timeit(lambda: next(filterfalse(set(a).__contains__, count(1))), number=100) 1.520096342996112 >>> timeit(lambda: min(set(range(1, len(a) + 2)) - set(a)), number=100) 1.987783643999137
(note that this is Python 3 and
range is the py2
The asymptotically good answer:
from heapq import heapify, heappop heap = list(A) heapify(heap) from heapq import heapify, heappop from functools import partial # A = [1,2,3] also works A = [1,14,2,5,3,7,8,12] end = 2 ** 61 # these are different and neither of them can be the sentinel = 2 ** 62 # first gap (unless you have 2^64 bytes of memory). heap = list(A) heap.append(end) heapify(heap) print(next(n for n, v in enumerate( iter(partial(heappop, heap), sentinel), 1) if n != v))
Now, the one above could be the preferred solution if written in C, but
heapq is written in Python and most probably slower than many other alternatives that mainly use C code.
Or the simple answer with good constants for O(n lg n)
next(i for i, e in enumerate(sorted(A) + [ None ], 1) if i != e)
This might be fastest of all if the list is almost sorted because of how the Python Timsort works, but for randomized the set-difference and iterating the first not in set are faster.
+ [ None ] is necessary for the edge cases of there being no gaps (e.g.
I would suggest you to use a generator and use enumerate to determine the missing element
>>> next(a for a, b in enumerate(myList, myList) if a != b) 4
enumerate maps the index with the element so your goal is to determine that element which differs from its index.
Note, I am also assuming that the elements may not start with a definite value, in this case which is
1, and if it is so, you can simplify the expression further as
>>> next(a for a, b in enumerate(myList, 1) if a != b) 4
Don't know how efficient, but why not use an xrange as a mask and use set minus?
>>> myList = [1,14,2,5,3,7,8,12] >>> min(set(xrange(1, len(myList) + 1)) - set(myList)) 4
You're only creating a set as big as
myList, so it can't be that bad :)
This won't work for "full" lists:
>>> myList = range(1, 5) >>> min(set(xrange(1, len(myList) + 1)) - set(myList)) Traceback (most recent call last): File "<stdin>", line 1, in <module> ValueError: min() arg is an empty sequence
But the fix to return the next value is simple (add one more to the masked set):
>>> min(set(xrange(1, len(myList) + 2)) - set(myList)) 5
import itertools as it next(i for i in it.count() if i not in mylist)
I like this because it reads very closely to what you're trying to do: "start counting, keep going until you reach a number that isn't in the list, then tell me that number". However, this is quadratic since testing
i not in mylist is linear.
Solutions using enumerate are linear, but rely on the list being sorted and no value being repeated. Sorting first makes it O(n log n) overall, which is still better than quadratic. However, if you can assume the values are distinct, then you could put them into a set first:
myset = set(mylist) next(i for i in it.count() if i not in myset)
Since set containment checks are roughly constant time, this will be linear overall.
I just solved this in a probably non pythonic way
def solution(A): # Const-ish to improve readability MIN = 1 if not A: return MIN # Save re-computing MAX MAX = max(A) # Loop over all entries with minimum of 1 starting at 1 for num in range(1, MAX): # going for greatest missing number return optimistically (minimum) # If order needs to switch, then use max as start and count backwards if num not in A: return num # In case the max is < 0 double wrap max with minimum return value return max(MIN, MAX+1)
I think it reads quite well
The naive way is to traverse the list which is an O(n) solution. However, since the list is sorted, you can use this feature to perform binary search (a modified version for it). Basically, you are looking for the last occurance of A[i] = i.
The pseudo algorithm will be something like:
binarysearch(A): start = 0 end = len(A) - 1 while(start <= end ): mid = (start + end) / 2 if(A[mid] == mid): result = A[mid] start = mid + 1 else: #A[mid] > mid since there is no way A[mid] is less than mid end = mid - 1 return (result + 1)
This is an O(log n) solution. I assumed lists are one indexed. You can modify the indices accordingly
EDIT: if the list is not sorted, you can use the heapq python library and store the list in a min-heap and then pop the elements one by one
H = heapify(A) //Assuming A is the list count = 1 for i in range(len(A)): if(H.pop() != count): return count count += 1
sort + reduce to the rescue!
from functools import reduce # python3 myList = [1,14,2,5,3,7,8,12] res = 1 + reduce(lambda x, y: x if y-x>1 else y, sorted(myList), 0) print(res)
Unfortunatelly it won't stop after match is found and will iterate whole list.
Faster (but less fun) is to use for loop:
myList = [1,14,2,5,3,7,8,12] res = 0 for num in sorted(myList): if num - res > 1: break res = num res = res + 1 print(res)
The easiest way would be just to loop through the sorted list and check if the index is equal the value and if not return the index as solution. This would have complexity O(nlogn) because of the sorting:
for index,value in enumerate(sorted(myList)): if index is not value: return index
Another option is to use python sets which are somewhat dictionaries without values, just keys. In dictionaries you can look for a key in constant time which make the whol solution look like the following, having only linear complexity O(n):
mySet = set(myList) for i in range(len(mySet)): if i not in mySet: return i
A solution that returns all those values is
free_values = set(range(1, max(L))) - set(L)
it does a full scan, but those loops are implemented in C and unless the list or its maximum value are huge this will be a win over more sophisticated algorithms performing the looping in Python.
Note that if this search is needed to implement "reuse" of IDs then keeping a free list around and maintaining it up-to-date (i.e. adding numbers to it when deleting entries and picking from it when reusing entries) is a often a good idea.
The following solution loops all numbers in between 1 and the length of the input list and breaks the loop whenever a number is not found inside it. Otherwise the result is the length of the list plus one.
listOfNumbers=[1,14,2,5,3,7,8,12] for i in range(1, len(listOfNumbers)+1): if not i in listOfNumbers: nextNumber=i break else: nextNumber=len(listOfNumbers)+1